 |
Description  |
|
|
BACKGROUND OF THE INVENTION
The present invention relates to surveying instruments, whose actual
readings, particularly the angle of elevation or horizontal direction
azimuth, are subject to levelling errors when the instrument is erected
and particularly to a theodolite having integrally connected apparatus for
determining the levelling errors of the instrument and providing a
corrective signal for error-compensation.
Various arrangements for stabilizing the spatial orientation of optical
systems are known, as well as to compensate for the deviation from an
ideal position. To stabilize entire instruments, it is known to mount them
on a gyroscopic platform. The expense connected with this arrangement is a
serious disadvantage. There has also been used means, for example,
gyroscopes, spirit levels, pendulums and the like, as a reference for
analyzing the rotary motion of an instrument. Thus the deviation of the
instrument from its true level position can be automatically compensated
by displacement of an optical element and/or the optical ray path. Such
direct compensation results in extraordinarily large difficulties,
particularly where incremental measuring methods are used, since
instrumental vibrations result in ambiguities and averaging problems. In
contrast to scale or code readings with a defined zero, incremental
systems measure only directional variances by counting of individual or
single steps during the movement from one direction to another. To modify
the extent of such movement being defined by the aiming points by an
amount corresponding to the error in horizontal orientation, cannot be
successfully accomplished with the use of simple means.
The object of the present invention is, therefore, to provide surveying
apparatus whose readings based on scale or code systems or for the
incremental system can be faultlessly corrected with relatively low cost
and at high satisfaction.
The foregoing objects, other objects as well as the numerous advantages of
the present invention, are set forth in the following disclosure.
SUMMARY OF THE PRESENT INVENTION
According to the present invention, a surveying instrument such as a
theodolite is provided with means for measuring the instrumental levelling
errors as well as the usual readings and with a computer which calculates
the error free values of the instrument, thereby compensating for the
errors in levelling.
In one embodiment, the corrected numerical value corresponding to a
horizontal direction determined by a target is calculated. The measured
value for any direction may be observed as an electrical signal obtained
by photoelectric conversion, electrical counting and interpolation of the
periods (fringes) of a moire pattern passing through a scanning device.
The value of the instrumental levelling error is taken from the control
current which serves to operate a position regulating circuit of a rotary
coil driven pendulum. The corrected direction is automatically calculated
by the computer from the measuring values present and may be shown
digitally.
In another embodiment, the instrumental levelling error is determined by
the output signal of a Schottky-Barrier (SB) photodiode fixedly mounted on
the instrument and illuminated by a light ray reflected from the surface
of a liquid mirror. A device using a moire pattern is capable of producing
an output measuring signal for the computer to calculate the correct
value.
The moire pattern may be scanned by a "Self-Scanned Photodiode Array"
converting the same to an electrical scanning signal which may then be
processed by a charge amplifier, an integrator and a "Sample-Hold
Circuit", the signal phase of the scanning signal is determined by an
analog-digital "Phase-Locked-Loop Circuit" (PLL).
Full details of the present invention are set forth in the following
description and illustration in the accompanying drawings of the invention
and its preferred embodiments.
BRIEF DESCRIPTION OF THE DRAWINGS
In the accompanying drawings:
FIG. 1 is a view of a theodolite illustrating the tilt axis error,
inclination measuring device and a computer having an indicator;
FIGS. 2a and 2b show the geometric situation of the instrument relative to
the several axes appearing on the inclination measuring device before and
after turning it by 180.degree., respectively;
FIG. 3 illustrates the relationship between the tilt axis and the error in
horizontal direction of the theodolite, in three dimensions;
FIGS. 4a and 4b are representations of the geometric situation in a
theodolite having an instrumental levelling error for mathematically
correcting the measuring values;
FIG. 5 illustrates one embodiment for determining the instrumental
levelling error utilizing a pendulum driven by a rotary coil with position
regulating circuit;
FIG. 6 illustrates a second embodiment for determining the instrumental
levelling error utilizing a Schottky-barrier photodiode, a liquid level,
illumination and evaluating electronics;
FIG. 7 is a circuit diagram of a Self-Scanned Photo Diode Array with
evaluating electronics for scanning the moire pattern;
FIG. 8 is a circuit diagram of a system of four photoelectric receivers in
line with evaluating electronics; and
FIG. 9 is a block diagram of computer apparatus for computing the error
free values to compensate for instrumental levelling errors.
DESCRIPTION OF THE INVENTION
The present invention is broadly illustrated in FIG. 1 in which is shown a
theodolite of known construction, generally depicted by the numeral 1,
with its transverse horizontal tilt axis K deviated from its position
normally perpendicular to the true vertical axis V (or plumb line). This
deviation is detected by a clinometer 2 secured to the side piece of the
frame of the theodolite. The clinometer 2 produces an output signal which
is fed to the input of a computer 3 which also processes signals from an
opto-electrical horizontal direction and elevation detector.
Examples of the clinometer 2 will be described in connection with FIGS. 5
and 6. Details about opto-electrical horizontal direction detectors and
elevation detectors are already known to those skilled in the present art
and further description here is only given in connection with Moire
pattern interpolation. This will be done by the description in connection
with FIGS. 7 and 8. A general lay-out of the computer will be described in
connection with FIG. 9. Reference for supplemental information about
standard usable opto-electrical horizontal and vertical direction
detectors can be made to:
German DT-AS No. 1,548,704 -- Hock, Heitmann
Swiss CH-PS No. 327,772 -- Williamson, Shepherd, Walker
British GB-PS No. 782,831 -- Dyson
French F-PS No. 2,113,114 -- Wieg, Preston
In order to digitally indicate the error in tilt axis position and the
corrected horizontal directions and angles of elevation, the computer 3 is
further provided with indicator devices 4.
The method for calculating the correct values thereby compensating for tilt
error is based upon the geometrical relationships inherent between the
theodolite elements and the horizontal and vertical directions and
bearings.
FIGS. 2a and 2b illustrate the angular relationship between the true
horizontal plane, indicated by the letter H, the tilt axis K of the
theodolite inclined at an angle i with respect to the horizontal plane H,
this inclination causing the errors in instrumental reading and being
measured by the clinometer, etc., and the axis A of a clinometer 2, which
in actual practice, the clinometer might take, and which deviates from K
by an angle .rho..
In FIGS. 2a and 2b, a clinometer 2 with analog indicator 5 for illustrative
purpose mounted on the instrument is shown. The error in levelling which
occurs between the tilt axis K and the horizontal axis H is defined by the
angle i. This angle may be eliminated by two settings of the clinometer 2,
one in a first position as seen in FIG. 2a, the second by turning the
instrument head (i.e., rotating its alidade) 200 grads (or 180.degree.).
FIG. 2b shows the situation after such turning. Numeral 6 indicates a null
angle reference direction, the angle .rho., indicates the unknown axis
error of the device 2 and s the angle between the reference direction 6
and a line perpendicular to the axis A. If L or R define the angle between
the vertical plumb line V (zenith) and the reference line 6 in FIG. 2a or
FIG. 2b, then we find
L = s + (i + .rho.)
and
R = s - (i - .rho.)
or
i = 1/2 (L - R).
briefly, as seen in FIG. 2a, the angle A6H is equal to (i + 92). Because of
the perpendicular intersection of the true vertical V with axis H, the
angle between the true vertical V and the perpendicular line to axis A is
also (i + .rho.). Similar geometric and trigonometric analysis will
indicate the correctness of the value (i - .rho.) for the similar angle of
FIG. 2b. The indicator 5 shows the analog value 1 or r for angles L or its
counterpart R.
Referring now to the three-dimensional diagram of FIG. 3, the horizontal
plane is defined by C.sub.1 C.sub.2 and K.sub.1 K.sub.1, K.sub.1 K.sub.1
indicating an ideally horizontal position of the instrumental tilt axis.
C.sub.1 C.sub.2 and K.sub.2 K.sub.2 show the position, the plane of the
instrumental horizontal circle might have in practice, the tilt axis being
now at an inclined position K.sub.2 K.sub.2. Note that the plane ZS,
K.sub.1 K.sub.1 vertical to the horizontal plane and Z'S, K.sub.2 K.sub.2
vertical to the plane of the instrumental horizontal circle are parallel.
From the error in tilt axis, that is angle i, an angle of error i' in a
horizontal direction .beta.' can be determined. As a result of the error
i, the sight line SP will move in the plane C.sub.1 PZ'C.sub.2 instead of
in the plane C.sub.1 QZC.sub.2. Thus, if a point P is sighted, it would be
projected toward the point C.sub.1 instead of at the point D. The angle i'
between the erroneous projection and the desired correct projection is
equal to DSC.sub.1 formed between the planes DPZ and C.sub.1 QZ and
constitutes the error of the measured horizontal direction when sighting
on the point P at an elevation .alpha..
It should be pointed out that the angle .alpha. appears actually, as will
be described later, between the sight line SP and the projection of this
line on the plane C.sub.1 C.sub.2, K.sub.2 K.sub.2 parallel to the
horizontal circle of the theodolite. Inspite of that, in a first
approximation the angle .alpha. is taken between the sight line and its
projection on the horizontal plane as K.sub.1 K.sub.1, C.sub.1 C.sub.2.
In the triangle ESF, the sin i' = EF/ES and in the right triangle PEF,
parallel to the plane formed by ZSZ' the tan i = EF/EP. Since the angle
.alpha. is determined by triangle PSE, PS being the radius of length r,
the sin .alpha. = PE/r and cos .alpha. = ES/r. Thus, sin i' = r sin
.alpha. .multidot. tan i/r cos .alpha. = tan i .multidot. tan .alpha.. For
small errors i in the tilt axis, the error in the horizontal direction can
be defined as i' = i .multidot. tan .alpha..
The computer 3, as shown in FIG. 1, calculates as will be described herein
from both (a) the inclination values R and L of the clinometer 2, and (b)
the measured horizontal direction .beta.', a corrected horizontal
direction .beta. = .beta.' + 1/2 (L - R) .multidot. tan .alpha..
In FIG. 3, it was assumed that the plane defined by the horizontal and
actual erroneous tilt axes K.sub.1 K.sub.2 ZZ'K.sub.1 K.sub.2 is parallel
to the vertical direction. If this is not the case, then there will exist
a general error in horizontal orientation. This means that an arbitrary
spatial position of the reference plane for the measuring values (being
rigidly fixed to the instrument, e.g. the horizontal circle plane)
relative to the horizontal plane will occur. FIG. 4a shows two views of a
theodolite coordinate system (X, Y, Z) being fixed to the instrumental
lower body (i.e., to the tripod). The Z-axis extends upwardly
perpendicular to the plane of the paper. The (X, Y) plane defines the
instrumental base, that is, the horizontal circle plane. The (X, Z) plane
defines the principal plane for the clinometer measurement. A clinometer
which is secured on the lower body will measure the angular deviation of
the X and Y axes from the horizontal plane.
Each target point is accociated with measuring values .rho., .alpha.,
.delta..sub.x and .delta..sub.y wherein:
.rho. = the horizontal angle between the target sight line or direction,
projected on the (X, Y) plane, and the X-axis, measured from X toward Y;
.alpha. = the angle of elevation between the target sight line, projected
on the (X, Y) plane, and the target sight line itself, measured from the
(X, Y) plane;
.delta..sub.x is the angular deviation of the X-axis from the true
horizontal plane. When the .delta..sub.x is greater than zero, then the
X-axis lies above the horizontal plane;
.delta..sub.y is equal to the angular deviation of the Y-axis from the true
horizontal plane. When .delta..sub.y is greater than zero, then the Y-axis
lies beneath the horizontal plane.
In the case wherein the instrumental base plane (X, Y).sub.o is ideally
levelled, the values for each target point P are .rho..sub.o,
.alpha..sub.o, .delta..sub.x.sbsb.o and .delta..sub.y.sbsb.o,
.delta..sub.x.sbsb.o and .delta..sub.y.sbsb.o being always equal to zero.
The values for .rho..sub.o and .alpha..sub.o can then be obtained from the
instrumentally measured values by the following mathematical
transformations.
.rho..sub.o = .rho. + .rho..sub.1 + .rho..sub.2
and
.alpha..sub.o = .alpha. + .alpha..sub.1 + .alpha..sub.2,
wherein
.rho..sub.1 = tan .alpha. (.delta..sub.x sin .rho. + .delta..sub.y cos
.rho.),
.rho..sub.2 = sin 2.rho./4 (.rho..sub.1.sup.2 -[.delta..sub.x.sup.2 +
.delta..sub.y.sup.2]),
.alpha..sub.1 = .delta..sub.x cos .rho. - .delta..sub.y sin .rho.
and
.alpha..sub.2 = -.rho..sub.2.sup.1 /2 tan.alpha..
.rho..sub.2 and .alpha..sub.2 are small corrections of the second order.
The measurement of inclination is thus independent on rotation of the upper
body or alidade of the theodolite. If, on the other hand, as shall now be
supposed, the inclinometer is fixed to the alidade of the theodolite, one
can take constantly .rho. = 0, (the target point lies in the (X, Z) plane)
and the measured clinometer values .delta..sub.x and .delta..sub.y are now
dependent on alidade rotation. Also in this condition, each target point P
is associated with two measuring values a and .alpha., as well as with two
values for levelling error .delta..sub.x, .delta..sub.y, namely:
a = the horizontal direction, with arbitrary null reference (corresponds to
.beta.' of FIG. 3 for general conditions discussed here);
.alpha. = the angle of elevation mesured from the horizontal circle plane
of the theodolite;
.delta..sub.x = the angular deviation of the plane of the horizontal circle
from the horizontal plane measured in the direction of the target;
.delta..sub.y = the angular deviation of the plane of the horizontal circle
from the horizontal plane measured perpendicular to .delta..sub.x.
By using the formula, a.sub.o = a + a.sub.1 + a.sub.2 and .alpha..sub.o =
.alpha. + .alpha..sub.1 + .alpha..sub.2 and .rho. = 0, one can calculate
then, for the instance of the ideal horizontal levelling of the apparatus,
the horizontal direction and the angle of elevation as follows:
a.sub.o = a + .delta.hd y .multidot. tan.alpha.
##EQU1##
In FIG. 5, there is illustrated one apparatus, according to the present
invention, for determining the error in horizontal levelling of the
theodolite comprising a rigid pendulum 7 mounted at one end to a wire
wound rotary coil 9 perpendicular to the axis of rotation; the coil being
journalled by a stretched ribbon in a frame, in the manner of galvanometer
or similar system 8. The system 8 is mounted on a base body 10. A pair of
photodiodes 11 is mounted on the body 10 adjacent the lower end of the
pendulum 7. The diodes 11 are illuminated through a slit-shaped opening in
the pendulum by a light-emitting diode 12 (not visible) which is in a
similar manner securely mounted on the body so that the output signal
obtained in a known manner as the difference signal of the diodes changes
with the position of the pendulum. To compensate for any change in
position of the journal axis of the coil 9 of the measuring device, the
pendulum 7 may be provided with a light weighted arm indicator (not shown)
extending toward the top, and a second photoelectric reading system
arranged diametrically to the system 11 and 12. The electrical output
signals of both of these reading systems can then be suitably combined and
summed.
The output of the diodes 11 is connected by a suitable conductor to an
electronic system, depicted by the numeral 13, which is also connected to
the light-emitting diode 12 and the coil 9 by suitable conductors. The
electrode system 13 includes an automatic position regulating loop circuit
of known design by which the relative angular position of the rotary coil
9 may be kept constant by a control current signal to the coil,
corresponding to the difference in the photoelectric signals from
photodiodes 11, even if there are changes in the inclination of the body
10. Thiscontrol signal, in the form of current signal, serves also as a
measure of inclination of the apparatus as a whole to the direction of
gravity (i.e. tilt), and is imposed on an output 14 which is fed to the
computer 3 and/or on an indicator 15. In case large angles of inclination
are to be considered, one can take into account with the computer 3 (FIG.
1) the fact that the signal on the output 14 will be proportional to the
sine of the angle of inclination.
The function of the apparatus so far described should be, without further
details, clear.
A second means according to the present invention for measuring angles of
inclination is shown in FIG. 6. This means is suited for two coordinate
measurement. A two coordinate responsive Schottky-Barrier (SB) photodiode
16 is mounted on a base plate 17 secured to the frame of the theodolite
instrument. A Schottky-Barrier photodiode, as is known in the art, is a
semiconductor photodiode of which one electrode has an extended light
sensitive surface with e.g. four electric connections at its
circumference, these connections receiving different amounts of current
according to their distance from a light spot on the extended surface. The
SB-photodiode 16 is illuminated by a light-emitting diode 18 via the
reflective surfaces of a liquid mirror 19, having a transparent glass wall
and a matching prism 20 on which light rays 21 are incident. The diameter
of the light beam 21 is small relative to the light responsive face of the
photodiode 16, and the relative position of the incidence point and
therefore the relative amounts of the resultant current signals are
dependent upon the inclination of the base plate 17. An electronic circuit
22 supplies the current power for the light-emitting diode 18 and
processes the output signals of the SB-photodiode 16 over the illustrated
conductors. The circuit 22 converts the signals into outputs for
indicating apparatus 23 and 24 for each of the two inclination components
respectively and provides electrical output pulse signals for the computer
3 on the outputs 25 and 26. Further details of the construction of the
liquid mirror optics between elements 16 and 18, pulse drive for the LED
18, analog-digital processing and counting of the measuring signal, etc.,
will be evident to the person skilled in the present art, although they
lie simultaneously in the scope of the present invention. The proper
function of the described apparatus depends on the constant and stable
horizontal position of the liquid mirror 19. The light beam 21 reflected
from the mirror 19 by total reflection is determined in its relative
position by the combination of four output signals from the four signal
outputs of the SB-photodiode 16. Thereby the inclination of the apparatus
can be determined.
FIG. 7 shows a diagram of a circuit system for exactly determining and
interpolating the relative position of a moire pattern. Such an array or
pattern may, in known manner, be used to measure electro-optically even
small changes in direction. In the present case a sector of the graduated
circle of the instrument is projected through suitable enlargement or
reduction on a diametrically opposite sector of the circle for generating
such a moire pattern to be photo-electrically scanned. The moire pattern
is formed of parallel light and dark relatively movable stripes, which run
together by rotating the angle, that is the graduated circle. The number
of stripes passing by a scanner can be counted by a sufficiently quick
counting system. A fraction of the moire pattern must subsequently be
correctly interpolated. The interpolation system has a time constant
suitable for temporal averaging of vibration and noise. A dynamic
measuring method can then be advantageously used, wherein no additive
measurement errors result.
The circuit according to FIG. 7 works with direct electro-optical scanning
or sensing of the moire pattern (similar to T.V. - scanners). To this end,
a "Self-Scanned Photodiode Array" 27 is used (e.g. solid state line
scanner RL-64P, Reticon Corp., Mountain View, California); that is, a
linear arrangement of, for example, 64 photodiodes on a semi-conductor
chip. An oscillator or generator 28 delivers a 5kHz.-signal triggering a
monoflop 30, to the array 27 to cause the diodes to serially read the
information from the moire pattern and to provide a video signal output
over conductor 29. The video signal passes through a charge amplifier 31,
into an integrator 32 and a Sample Hold Circuit 33, at whose output the
local brightness distribution of the moire pattern appears as a temporal
step wave. The position of the moire pattern relative to the last scanning
diode determines the temporal relation of the step wave relative to the
sensing pulse (end of the scan) of this diode, which is delivered over the
conductor 34 from the array 27.
To measure this temporal position an analog-digital Phase Lock Loop System
(PLL) is employed. It comprises, amongst others, a counter 35, which
counts a 62.5kHz. signal from oscillator-generator 28 and which is re-set
by the end of the scan signal passed over the conductor 34. The outputs of
the counter 35 and the Sample Hold Circuit 33 are connected to the input
of a multiplierphase comparator 36. The resultant product signal is
switched via a low pass filter 37 and a voltage to frequency transformer
(VFO) 38 with plus and minus outputs to an up/down counter 39 to which is
connected an indicator 40.
The function of this (PLL) circuit can briefly be described as follows: The
counter 35 supplies at its output a rectangular or square wave signal with
a temporal period equal to the video (step wave) signal at the output of
Sample-Hold Circuit 33. The phases of both signals are compared in the
multiplier-phase comparator 36 and the phase of the square wave signal
from the counter 35 is re-set, after each period, for a time until both it
and the video signal are shifted out of phase by 90.degree.. The shifting
of the square wave signal from the counter 35 relative to the end-of-scan
signal on conductor 34 is available on the counter 39 for digital display
on a display 40. In stable condition of this circuit, this shift of the
signals is equal to the phase shift of the moire pattern on the scanner
element 27 relative to the end-of-scan signal and therefor is equal to the
interpolation angle. The described embodiment which can be generally
called an interpolator provides a maximum digital displacement value of
800 on the counter 39 each single step of the counter 39 corresponding to
an angle of 1/4 cc (centesimal).
In principle, the PLL circuit produces a square wave signal, from counter
35, whose phase is locked to the phase of the step wave signals from S.H.
switch 33.
A further circuit for scanning or interpolating the moire pattern is seen
in FIG. 8. Here, the moire pattern is simultaneously scanned by a system
41 of four photodiodes 42, 43, 44 and 45 arranged in a row or line. Each
diode covers one-fourth of a moire period. The levels of the
photoelectrical output signals of the diodes 42, 43, 44 and 45 are
approximately proportional to the functions of sine, cosine, -sine,
-cosine of the directional angle .rho. of a given moire fringe. The system
41 is connected to two differential amplifiers 46,47 which process the
signals sin .rho., -sin .rho. and cos .rho., -cos .rho.. The output
signals of these amplifiers 46 and 47 are multiplied in multipliers 48, 49
with respectively a 1 kHz. reference signal sin wt or cos wt supplied from
an oscillator - generator 50 with a 90.degree. - phase shifter 51. The
product signals are summed in an adder 52. A phase meter 53 with an
indicator produces an interpolation angle .rho. from the summed signal cos
(wt - .rho.) from the adder 52 and the reference signal cos wt from the
oscillator - generator 50.
The function of this interpolation circuit is clarified using the addition
theorem
cos (wt - .rho.) = cos wt .multidot. cos .rho. + sin wt .multidot. sin
.rho..
The sum of both products signals of the multipliers 48 and 49 constitutes
an oszillation cos (wt - .rho.), phase shifted on the signal (cos wt) of
the oscillator 50 by the interpolation angle .rho.. This phase angle is
digitalized in the phase measuring apparatus 53.
In the block diagram of FIG. 9 there are shown two angle encoders 60 and 61
to determine the horizontal directtion (azimuth) a and the angle of
elevation .alpha.. By these angular indicators, electrical angular step
pulses are derived which are summed respectively in the subsequently
arranged incremental counters 62, 63, taking into account their correct
sign. In order to simplify the operation, the angle of elevation must be
measured directly without the need for subsequent or later zero
correction. In order to do this, a null detector 64 with a null mark on
the vertical graduated circle of the theodolite is needed which, by
swinging of the theodolite telescope through the vertical axis of the
instrument, automatically sets the increment counter 63 to zero.
The counters 62 and 63 are arranged with interpolators 65, 66 (for example,
as described with FIG. 7 or FIG. 8). The intermediate values from the
interpolators 65 and 66 are respectively added to the incremental sums
from 62 and 63 in adders 67 and 68. The interpolation null point 0.sup.cc
(zero centesimal seconds) is set by electronic adjustment. The horizontal
graduated circle is not provided with a null marker. The directional value
of each individual target point can, however, be brought to 0.sup.g,
0.sup.c and 0.sup.cc by activation of a zero setting circuit 69.
In addition to providing the values a and .alpha., inclination measuring
devices 70 an 71 (for example, according to FIG. 5 and FIG. 6) provide the
angular deviations .delta..sub.x and .delta..sub.y, as defined with FIG.
4, in the form of electrical signals. From these values, a computer
device, for example, in the form of a known programmable micro-processor,
can determine the correct directional and angular values a.sub.o,
.alpha..sub.o, according to the mathematical transformation formulae shown
in connection with FIG. 4. This process is schematically illustrated by a
tangential-functional unit 72 which produces the tan .alpha., a multiplier
73 which produces .delta..sub.y .multidot. tan .alpha. and an adder 74,
for calculating:
a.sub.o = a + .delta..sub.y .multidot. tan .alpha.,
as well as a second adder 75 which computes the elevation angle
.alpha..sub.o = .alpha. + .delta..sub.x.
These results are fed in electrical form, together with the inclination
components .delta..sub.x and .delta..sub.y, to an indicator unit 76. The
indicator unit has four windows 77, 78, 79 and 80. The first window 77
shows the corrected horizontal direction a.sub.o ; the second window 78
shows the corrected elevational angle .alpha..sub.o : the third window 79,
the inclination .delta..sub.x of the apparatus in the target direction,
and the fourth window 80 the inclination .delta..sub.y of the apparatus in
the direction perpendicular thereto. The indication of the inclination of
the apparatus or instrument can be used to obtain the fine adjustment of
the horizontal levelling of the apparatus.
In addition to the described embodiment, the present invention as well as
other embodiments may be employed, for example, to measure the path of a
projectile and file control system.
From the foregoing, it will be clearly seen that the values corrected for
the compensation of errors in horizontal levelling of the theodolite,
either the angles of elevation or the horizontal directions can be easily
obtained. In doing so, the photoelectric sensing apparatus shown in FIGS.
5 and 6 (i.e., the pendulum and Schottky-Barrier photo-electric systems)
measure simultaneously the two components .delta..sub.x and .delta..sub.y
of the levelling error.
In each instance, the corrected values are digitally displayed.
Various modifications, changes and embodiments have been suggested, others
may be obvious to those skilled in the art. This disclosure is therefore
to be taken as illustrative of the present invention and not limiting
thereof. In the event any portion of my Swiss Application, No. 11 348/75,
is not specifically set forth herein, the same is made reference to as if
more fully disclosed. Reference may also be made to the following for more
complete details of specific elements and electronic components employed
herein:
______________________________________
List of standard or commercial items of suitable electronic
components which may be used in the computer
Ref. No.
Function Manufacturer Catalog No.
______________________________________
72 to 75
"slide rule calculator"
National Semicon-
MM 5760
ductor Corp.
Santa Clara
California 95051
72 to 75
calculator programmer
same MM 5765
72 to 75
quad-switch RCA CD 4066 A
72 to 75
decoder-switch RCA CD 4667 B
72 to 75
counter 7-stage
RCA CD 4024 A
77 to 80
decoder RCA CD 4514 B
72 to 75
multiplexer dual
RCA CD 4097 B
72 to 75
dual decoder RCA CD 4555 B
77 to 80
LC-display RCA CD 4056 A
______________________________________
Items of electronic components in the inclination apparatus
16 Schottky-Barrier photo
United Detector
PIN SC/10
diode Technology
Santa Monica
California
18 diode RCA 3001
______________________________________
* * * * *
|
|
 |
|
 |
Description |
|
